1. 7.2 – SOLVING LINEAR SYSTEMS GRAPHICALLY SYSTEMS OF LINEAR EQUATIONS

2. TODAYS OBJECTIVES Students will be able to solve problems that involve systems of linear equations in two variables graphically and algebraically, including: Determine and verify the solution of a system of linear equations graphically, with and without technology Explain the meaning of the point of intersection of a system of linear equations

3. SOLVING LINEAR SYSTEMS GRAPHICALLY The solution of a linear system can be estimated by graphing both equations on the same grid. If the two lines intersect, the coordinates (x,y) of the point of intersection are the solution of the linear system. Solution to the system

4. SOLVING LINEAR SYSTEMS GRAPHICALLY 3x + 2y = -12 -2x + y = 1 We can use the graphs to estimate the solution of the linear system. The set of points that satisfy both equations lie where the two graphs intersect. From the graph, the point of intersection appears to be (-2, -3).

5. VERIFYING YOUR ESTIMATE

6. EXAMPLE

7. The point of intersection appears to be (6, 2). Verify the solution by substituting x = 6 and y = 2. 6 + 2 = 8; 8 = 8 3(6) – 2(2) = 14; 18 – 4 = 14; 14 = 14 The left sides equal the right sides, so x = 6, and y = 2 is the solution of the linear system.

8. SOLVING A PROBLEM BY GRAPHING A LINEAR SYSTEM One plane left Victoria at noon to travel 1400 km to Medicine Hat at an average speed of 400 km/h. Another plane left Medicine Hat at the same time to travel to Victoria at an average speed of 350 km/h. A linear system that models this situation is: where d is the distance in km’s from Victoria to Medicine Hat and t is the time in hours since the planes took off. d = 1400 – 400t d = 350t

9. a)Graph the linear system. b)Use the graph to solve this problem: When do the planes pass each other and how far are they from Medicine Hat? Solution: The planes pass each other when they have been travelling for the same time and they are the same distance from Medicine Hat. Solve the linear system to determine values of d and t that satisfy both equations. For the graph of equation (1), the slope is -400 and the vertical intercept is 350. For the graph of equation (2), the slope is 1400 and the vertical intercept is 0.

10. A) GRAPH THE LINEAR SYSTEM Distance (km) Time (h) d = 1400 – 400t d = 350t

11. B) WHEN DO THE PLANES PASS EACH OTHER AND HOW FAR ARE THEY FROM MEDICINE HAT? The graphs appear to intersect at (1.9, 650); that is, the planes appear to pass each other after travelling for 1.9 hours and at a distance of 650 kilometers from Medicine Hat. Use the coordinates of the point of intersection to verify the solution. 400(1.9) = 760 km. So, it will be: (1400 – 760) km, or 640 km’s from Medicine Hat. The plane travelling from Medicine Hat to Victoria travels at 350 km/h, so, in 1.9 hours, its distance from Medicine Hat will be 350(1.9) km = 665 km. These times and distances are approximate because these measures cannot be read accurately from the graph. 0.9 hours = 54 minutes. The planes pass each other after travelling for approximately 1 hour, 54 minutes and when they are approximately 650 km from Medicine Hat.

12. EXAMPLE A) Write a linear system to model this situation: To visit Head-Smashed-In Buffalo Jump in Alberta, the ticket price is $5 for a student and $9 for an adult. In one hour, 32 people entered the center and a total of $180 in admission fees was collected. B) Graph the linear system then solve this problem: How many students and how many adults visited the center during this time?

13. EXAMPLE Equationa-intercepts-intercept 32 2036

14. EXAMPLE Data is discrete so should actually be a series of points The point of intersection appears to be (27, 5). Verify the solution: 27 students x $5 = $135 5 adults x $9 = $45 32 people for $180 The total number of people is 32 and the total cost is $180, so the solution is correct. 27 students and 5 adults visited the center.